288
Middle East Journal of Applied Sciences 4(2): 288-299, 2014
ISSN 2077-4613
Corresponding Author: M.A.Wassel, Department of chemistry, Faculty of Science, Al-Azhar university, Cairo, Egypt.
E-mail: [email protected]
Kinetic and thermodynamic studies of Co(II), Ni(II) and Mn(II) adsorption using
ResinexTM
K-8H resin.
M.A. Wassel, A.A. Swelam, A.M.A. Salem, A.S. El-Feky
Department of chemistry, Faculty of Science, Al-Azhar university, Cairo, Egypt
ABSTRACT
Kinetic and thermodynamic studies have been carried out on the adsorption of Co(II), Ni(II) and Mn(II) by
strong cation exchange of ResinexTM
K-8H (H+-form) resin. The adsorption process has been investigated as a
function of adsorb ate concentration, solution acidity, contact time, adsorbent amount, and temperature. The
experiments were preformed in batch mode, where the initial concentration on the solution samples were 0.001,
0.0025, 0.005 and 0.01 (mg/l), HCl acid concentration range was 0.01–1.5 (mg/l) and sorbent amount were 0.25,
0.5,1.5 and 3.0 g. Equilibrium isotherm data were analyzed using Langmuir, Freundlich, and Temkin isotherm
models. The results showed that the adsorption process was well described by Freundlich and Langmuir
isotherm models. The kinetic data were analyzed using first-order and pseudo-second order kinetic models.
Theresults indicated that adsorption fitted well with the first-order for Mn(II) and pseudo-second order kinetic
model forCo(II) and Ni(II). The activation energy, Ea was determined by plotting ogKD versus 1/T,as well as the
thermodynamic parameters(∆H, ∆S and ∆G) were determined at different temperatures (25, 35 and 450C).The
values of Co(II) and Ni(II) show endothermic while for Mn(II) show exothermic process. In this study, ion
exchange kinetic mechanism for heavy toxic metal ions, Co(II), Ni(II) and Mn(II) is carried out by Strong cation
exchange of ResinexTM
K-8H (H+-form) resin under different conditions in aqueous solution to validate the
practical application of this strong cation exchange of ResinexTM
K-8H (H+-form) resin in wastewater treatment
process.
Key words: Thermodynamic, Kinetic, Temperature, ResinexTM
K-8H, Adsorption.
Introduction
Divalent metals contamination exists in the aqueous waste streams of many industries, such as metal plating
facilities, mining operations, nuclear power plant and tanneries. The soils surrounding many military bases are
also contaminated and pose a risk of ground water and surface water contamination due to the divalent metals.
Divalent metals are Cd(II),Cr(III),Co(II),Pb(II) and Hg(II) not biodegradable and tend to accumulate
inliving organisms, causing various diseases and disorders (Susan et al,1999, Netzer and Hughes, 1984, Gomez-
Lahoz et al, 1993). Cobalt, a natural element present in certain ores of the Earth’s crust, is essential to life in
trace amounts. It exists in the form of various salts. Pure cobalt is anodorless, steely-gray, shiny, hard metal.
Everyone is exposed to low levels of cobalt in air, water and food. An average of 2 g in drinking water has been
estimated. Cobalt has both beneficial and harmful effect son health. The permissible limits of cobalt in the
irrigation water and livestock watering are0.05 and 1.0 mgdm_3, respectively (Wang et al, 2008).
With a better awareness of the problems associated with cobalt, research studies related to the methods of
removing cobalt from wastewater have drawn attention increasingly. Cu(II) and Ni(II) are mainly employed in
electroplating, pesticides, herbicides and tannery industries. The effluents of these industries usually contain
Cu(II) and Ni(II) which can cause environment problems and serious toxicological concerns (Wang et al, 2008).
The current technologies to remove Cu(II) and Ni(II) from water/wastewater include chemical precipitation,
adsorption and membrane process. Among these technologies, adsorption is the most common approach for
removing divalent metal ions from water/wastewater with high efficiency and easy operation. Many solid
materials as adsorbents have been investigated, such as activated carbons (AC), polymeric resins and natural
bio-adsorbents(NBA). Comparing with AC and NBA, polymeric resins have been used more widely in the
removal of divalent metals from water (Niu et al, 2010, Tugba et al, 2010).
The synthesis and characterization of control ledpore silica modified with N-propylsalicylaldimine has been
performed (Abou-El-Sherbini et al, 2002). B/Si ratio of 6.5/1 inborosilicate glass was found effective in
obtaining highly porous silica by acid leaching which led tohigh exchange capacity (CIE11=0.36 mmole Cug-1
,
pH 5.5) in the obtained ion exchanger (IE11). The complexation behavior of IE11 with Mn(II), Co(II), Ni(II),
Cu(II), Hg(II), Cr(III), Fe(III) and UO2(II) was investigated and confirmed byelectronic and infrared spectra and
thermal analysis. Adsorption of Mn(II) on Turkish kaolinite required 120 min toreach equilibrium (Yavuz et al,
2003).
289 Middle East j. Appl. Sci., 4(2): 288-299, 2014
In the solution temperature range of 298 to313 K, the first order rate coefficient increased from 1.20×10
-3
to1.90×10-3
min-1
(experimental conditions: adsorbent 1.0 g and particle size 200 mesh).
Materials And Methods
Materials
All the materials and chemicals (Aldrich, USA) were used as received with analytical grade. Stock
solutions of Co(II), Mn(II) and Ni(II)were prepared by dissolving its chloride (AR Grade) in distilled water. The
stock solution was diluted with distilled water to obtain the desired concentrations. Strong cation exchange of
ResinexTM
K-8H (H+-form) used in this work from Jacobi Swedish Company. Prior to use, the resin was
converted to the hydrogen (H+) form by washing it in 1 M HCl followed by further washing in deionised water.
The resin regeneration procedures follow the recommendations provided by the manufacturers. The resin-H was
dried and kept at room temperature in a desiccators until it was used.
The adsorption capacity in mg/g of the adsorbent (qe) and the metal ion adsorption percentage (Ad%) were
obtained by Eqs. (1) and (2),
qe = 𝐶𝑜−𝐶𝑒 𝑉/1000
𝑊 (1)
Ads% = 𝐶𝑜−𝐶𝑒 𝑥100
𝐶𝑜 (2)
where C0 and Ce are the initial and final metal ion concentrations (mg/l), respectively, V is aqueous phase
volume (ml) and W is the weight of adsorbent used (g). The data of isotherms were obtained after an
equilibrium time of 24 h. After the equilibrium time, the concentrations were determined by AAS varion 6
(Analytik Jena AG Konrad-Zuse-StraBe 1 07745 Jena).
Batch adsorption studies:
Adsorption studies were carried out in a batch mode by shaking0.5 g resin in 50 mL solution of Co(II),
Ni(II) and Mn(II) with concentration range from 158 to 675 mg/lon to the water bath shaker at100 rpm stirring
speed. Effect of solution acidity on the Co(II), Ni(II) and Mn(II) adsorption onto ResinexTM
K-8H was conducted
through varying the acidity of HCl solution in the range 0.01–3.0 M . Furthermore the adsorption studies were
also carried out by varying time interval (5–210 min) at 452mg/l of Co(II), Ni(II) and Mn(II) to optimize the
time required for the removal of Co(II), Ni(II) and Mn(II) from aqueous solution.
Discussion:
Effect of solution acidity:
Hydrochloric acid was used as complexing agent in a wide range of concentrations namely, 0.01 to 3.0 M.
Because the influence of this acid, hydrogen ion is governed by the mass reaction equation for a simple
exchange action of the chloride ion by lowering the effective concentration of the cation in solution through
complex formation. In order to investigate the effect of acidity solution on the metal ions uptake on
ResinexTM
K-8H strong acid cation exchange resin, series of experiments were carried out at 25oC using 0.50 g
ResinexTM
K-8H, and at a constant concentration, 452 mg/L of M+2
(M+2
=Ni(II), Co(II) and Mn(II)) in aqueous
solution with alter initial acidity values from 0.1 to 3.0M. The equilibrium uptake, qe (mg/g) of Ni(II), Co(II)
and Mn(II) on ResinexTM
K-8H from different acidic media was carried out. The effect of HCl at acid
concentration ranging from 0.01 to 1.5 M on the uptake of these metal ions are presented in Fig. 1. The
equilibrium sorption data indicate that: (i) At low acid concentration the metal cations exhibit generally strong
uptake and high affinity with the ResinexTM
K-8H matrix. This behavior is a prominent for all sorption
processes. However, (ii) With increasing acid concentration the H+ increase and further competes the exchange
sites. This behavior indicates that the ion exchange equilibrium shown in Eq.3:
RSO3- H
+ (exchange) + M
2+ (aqueous) ⇌ (RSO3)2
2-M + 2H
+ (3)
is predominant in back direction with the increase in acid concentration. (iii) Within the studied acid
concentrations range, in general, the sorption of cations in majority follows the selectivity order; Co(II) ˃
Ni(II)˃Mn(II). This may be explained in terms of the stability constants of the complexes which the metal ions
form with these acids. This acid might form rather stronger complexes with Co(II) ˃ Ni(II)˃Mn(II). According
290 Middle East j. Appl. Sci., 4(2): 288-299, 2014
to the above reaction (Eq. 3), low acidity will favor forward reactions whereas high acidity will favor backward
reactions. Although all these listed adsorption reactions might take place, their extent (completeness) for
specific ion species is very different due to the different affinity and selectivity of the resin to positively charged
ions, which the base for the adsorption processes.
Fig. 1 shows the uptake of Co(II), Ni(II) and Mn(II as a function of acidity. It can be seen that the higher of
metal ions uptake is maximum at acidity of 0.01M. At higher than 1.0M the uptake decreases continuously until
it vanishes (0%) at 3.0 M for each these metal ions.
Fig. 1: Effect of HCI concntratio ns for the adsorption uptake of Co (II), Ni (II) and Mn (II). At 25
oC.
The first stage of ion exchange is deprotonation of the sulphonic group of ResinexTM
K-8H which is
represented by Eq. 3. The zero percent removal at 3.0 M can be attributed to the fact that at higher acidity, the
concentration of H+ in the adsorption medium shifts the equilibrium as shown in Eq. 3 to the left direction. This
means that the sulphonic groups of the cation exchange resin do not ionize and the ion exchange sites on the
cation exchange resin surface are still protonated, under such conditions the metal ions do not exchange and
remain in the solution. As the acidity decreases from 3.0 to 0.01 M, the deprotonation equilibrium is shifted to
right and as a result, the adsorption capacity increases until it reaches its maximum values at 0.01 M(Mouni et
al, 2011).
Effect of adsorbent dosage:
The effect of adsorbent dosage on the percentage removal of Co(II), Ni(II) and Mn(II) by ResinexTM
K-8H
strong acid cation exchange resin are depicted in Fig.2, it can be seen that for Co(II) and Ni(II), as the dosage
increased from 0.25 to 1.5 g at 250C, the adsorption capacity of metal ions at equilibrium, qe, shows increases.
Additionally, higher adsorbent dosage, i.e., more than 1.5 g, complete sorption occur, while Mn(II) show
complete sorption after 3.0 g of the ResinexTM
K-8H (Sari et al, 2007, Azouaou et al, 2010,Iqbal et al,
2009)indicating that a larger quantity of readily active sites are available for adsorption.
Fig. 2: Effect of amount of the Res inex TM K-8H on the removal percentage of Co (II), Ni (II) and Mn (II). at
25 oC.
291 Middle East j. Appl. Sci., 4(2): 288-299, 2014
Effect of contact time and adsorption kinetics:
The obtained data for the Co(II), Ni(II) and Mn(II) removal from aqueoussolution using the ResinexTM
K-
8H is presented in (Fig. 3). The adsorption of Co(II), Ni(II) and Mn(II) from aqueous solutiononto the
ResinexTM
K-8H was rapid at the start of experimentand then rate of adsorption become slow down. The
maximumamount of Co(II), Ni(II) and Mn(II) from aqueous solutions wasadsorbed onto the ResinexTM
K-8H
within 150 min for Co(II), Ni(II) and 210 min for Mn(II) respectively, thenno significantchange was observed.
Thus the time of equilibriumfor the Co(II), Ni(II) was 150 min and 210 min forMn(II) respectively, then no
significant change was observed. Thus the time of equilibrium for the Co(II), Ni(II) was 150 min and 210 min
for Mn(II) adsorption onto the ResinexTM
K-8H ion- exchange resin from aqueous solutions.Theprobable reason
for rapidadsorption of Co(II), Ni(II) and Mn(II) onto the ResinexTM
K-8H from aqueous solution may be more
available active sites in theResinexTM
K-8H for adsorption. In addition the –SO3H andgroups in the ResinexTM
K-
8H were responsible forthe complex formation between metal ions Co(II), Ni(II) and Mn(II) andfunctional
groups (–SO3H) (Dam and Kim, 2009,Vellaichamy and Palanivelu , 2011). However the more activesites may
not be available in the ResinexTM
K-8H for furthermetal ions adsorption with progress of contact time.
Fig. 3: Effect of contact time on the adsorption uptake of Co (II), Ni (II) and Mn (II). at 25 oC.
The pseudo-first-order and pseudo-second-order also intraparticlediffusion kinetic models were applied to
determine the adsorptionrate of Co(II), Ni(II) and Mn(II) onto the ResinexTM
K-8H.The linearequation for
pseudo-first-order kinetic model can be expressed as:
log(qe− qt) = logqe,1.− k1t (4)
Lagergren showed that the rate of adsorption of solute on the adsorbent is based on the adsorption capacity
and followed a pseudo-first-order equation (Lagergren et al, 1898 ,Yang and Al-Duri, 2005) which is often used
for estimating k1 considered as mass transfer coefficient in the design calculations. where qe and qt are the
amounts of the metal ion adsorbed (mg/g) atequilibrium time and at any instant of time t, respectively, and k1
(L/min) is the rate constant of the pseudo-first-order adsorption.The plot of log(qe− qt) versus t gives a straight
line (Fig.4) for the pseudo first-order adsorption kinetics, from the adsorption rate constant, k1, is estimated.
Ho developed a pseudo second-order kinetic expression for the adsorption system of divalent metal ions.
This model has since been widely applied to a number of metal/sorbent adsorption systems.The adsorption of
Co(II), Ni(II) and Mn(II) onto the ResinexTM
K-8H resin at a shorttime scale may involve a chemical sorption
which implies the strong electrostatic interaction between the ResinexTM
K-8Hfunctional groups surface and
each of Co(II), Ni(II) and Mn(II).The linearequation for pseudo-second-order kinetic model can be expressedas
(McKay and Ho, 1999).The second-order kinetics equation is described as in the following form:
𝑡
𝑞𝑡 =
1
𝑘2𝑞𝑒22 +
𝑡
𝑞𝑒 (5)
where k2 (g/mg min) is the second-order rate constant. The product k2qe22 is the initial adsorption rate
“h”(mg/g min):
h = k2qe22 (6)
292 Middle East j. Appl. Sci., 4(2): 288-299, 2014
Fig. 4: Pseudo-first order kinetic plots for the adsorption uptake uptake of Co (II), Ni (II) and Mn (II) at diffrent
temperatures
Which h can be regarded as the initial adsorption rate as t approaches 0. Under such circumstances, the plot
of t/qtversus t should give a linear relationshipas in (Fig.5), which allows the computation of qe and k2.Where k2
is the pseudo-second-order rate constant (g mg-1
min-1
). The qe1, qe2,k1 and k2 values for different temperatures
of Co(II), Ni(II) and Mn(II) solutions were calculated from their respected plots.
Fig. 5: Pseudo- second kinetic plots for the adsorption uptake uptake of Co (II), Ni (II) and Mn (II) at diffrent
temperatures
The obtained qe1, qe2, k1, k2 and correlation coefficient(R2) values are tabulated in Table 1. The R
2 values of
Co(II) for pseudo second-order kinetic model are relatively higher than pseudo-first order kinetic model
adsorption. However, the experimental qe values are very close to the calculated qe2 values for pseudo-second-
order kinetic model.
These results implied thatthe adsorption of Co(II), onto the ResinexTM
K-8H obeyed second order model
kinetic model (McKay and Ho, 1999,Chen and Li, 2010),while opposite trend was observed for the Ni(II) and
Mn(II), where the R2 values for pseudo first-order kinetic model are relatively higher than pseudo-second order
kinetic model adsorption. These results implied that the adsorption of Ni(II) and Mn(II), onto the ResinexTM
-K-
8H obeyed first-order kinetic model. The diffusion ofmetal ions cannot be explained on the basis of pseudo-
first-order and pseudo-second-order kinetic model.
Due to this reason, intraparticle diffusion model was applied to estimate the diffusion of Co(II), Ni(II) and
Mn(II) in the ResinexTM
K-8H using Weber–Morris intraparticle diffusion model (Weber et al. 1963):
qt= kpt1/2
+ C (7)
where kp is the in traparticle diffusion rate coefficient (g mg-1
min1/2
) and C provides an idea about the
thickness of the boundary layer. The plot of qt vs. t1/2
as in (Fig.6) shows the three straight-line portions with
three different slopes and intercepts values. First portion of curves indicates the boundary layer diffusion while
293 Middle East j. Appl. Sci., 4(2): 288-299, 2014
final linear portion is a result of the intra-particle diffusion. Boundary layer is dominant if the intercept values
are high as in Ref. (Oubagaranadin et al, 2007).
Table 1: Kinetic parameters for of Ni(II), Co(II) and Mn(II) on ResinexTM K-8H in aqueous solution.
Pseudo first-order model Pseudo second-order model Intraparticle diffusion model
qe,1,cal K1 R2qe,2,cal K2 h R2 Kint C R2
--------------------------------- ------------------------------------------ ----------------------------------- (mg/g) (min-1) (mg/g) (g/mg min) (mg/g min) (mg/g min-0.5) (mg/g)
------------------------------------------------------------------------------------------------------------------------------
Ni(II) Temp.K
298 24.40 0.0220 0.9998 39.70 1.5x10-3 2.36 0.9907 2.21 11.43 0.9551
308 28.64 0.0222 1.0000 45.50 1.7x10-33.52 0.9936 2.63 11.38 0.9694 318 29.43 0.0230 0.9970 47.00 1.9x10-3 4.20 0.9936 2.60 13.87 0.9574
Co(II)
298 7.56 0.0290 0.9955 44.09 12.0 x10-323.30 0.9997 0.68 35.92 0.9387
308 7.99 0.0356 0.9963 44.70 13.0 x10-3 25.98 0.9998 0.65 37.03 0.9126
318 8.45 0.0366 0.9846 45.45 15.0 x10-330.99 0.9999 0.61 38.25 0.8898
Mn(II) 298 17.26 0.0286 0.9993 30.27 2.9 x10-32.66 0.9971 1.24 12.51 0.9379
308 16.76 0.0161 0.9904 28.43 2.2 x10-3 1.87 0.9916 1.25 9.85 0.9806
318 16.20 0.0141 0.9984 26.84 1.7 x10-3 1.22 0.9853 1.32 6.42 0.9876
Fig. 6: Plots of Weber-Morris for the adsorption of uptake of Co (II), Ni (II) and Mn (II) at 25
oC
The intercept values for Ni(II), Co(II) and for Mn(II) is 11.43, 35.92 and 12.51mg g-1
respectively. The
obtained values indicated that adsorption of Co(II), Ni(II) and Mn(II) onto the ResinexTM
K-8H was controlled
through a boundary layer effect.
Effect of concentration and adsorption isotherm:
The adsorption of Co(II), Ni(II) and Mn(II) onto the ResinexTM
K-8H at 250C and different concentrations is
depicted in Fig. 7.It was observed that the adsorption of Co(II), Ni(II) and Mn(II) onto theResinexTM
K-8H
increased with rise in concentration of these metal ions from 158 to 675mg L-1
. This is attributed to the greater
driving force through a higher concentration gradient at high metalions concentration according to (Acemioglu,
2005, Hameed et al,2008, Ramkumara and Mukherjee, 2007).Thus the developed ResinexTM
K-8H can be
efficiently used for the removal of high concentration Co(II), Ni(II) and Mn(II) from aqueous solutions. The
surface property and affinity of ResinexTM
K-8H for Co(II), Ni(II) and Mn(II) removalcan be determined using
the different adsorption isotherm models.
294 Middle East j. Appl. Sci., 4(2): 288-299, 2014
Fig. 7: Effect of initial metal ion concen tration on the adsorption uptake of Co (II), Ni (II) and Mn (II). at 25
oC.
The obtained equilibrium data from the adsorption of Co(II), Ni(II) and Mn(II) onto the ResinexTM
K-8H
fitted to the linear equation of Langmuir, Freundlich, and Temkin and Pyzhe isotherm models. The linear
equation for Langmuir, Freundlich and Temkin isotherm models are expressed as follows:
The model takes the following linear form:
𝐶𝑒
𝑞𝑒 =
1
bQo+
𝐶𝑒
Qo (8)
where Qo is the quantity of adsorbate required to form a single monolayer on unit mass of adsorbent (mg/g)
and qe is the amount adsorbed on unit mass of the adsorbent (mg/g) when the equilibrium concentration is Ce
(mg/l) and b (L/mg) is Langmuir constant that is related to the apparent energy of adsorption. As in Eq.(3)
shows that a plot of (Ce/qe) versus Ce should yield a straight line if the Langmuir equation is obeyed by the
adsorption equilibrium.
The slope and the intercept from (Fig.8) of this line yield the values of constantsQo and b respectively. A
further analysis of the Langmuir equation can be made on the basis of a dimensionless equilibrium parameter,
RL (Altin et al, 1998), also known as the adsorption factor, given by Eq. (9):
RL= 1
1 +𝑏𝐶𝑜 (9)
The value of RL lies between zero and one for a favorable adsorption, while RL> 1 represents an
unfavorable adsorption, and RL = 1 represents the linear adsorption, while the adsorption operation is
irreversible if RL =0.
Fig. 8: Langmuir plot for the adsorption of Co (II) at diffe rent tem peratures.
295 Middle East j. Appl. Sci., 4(2): 288-299, 2014
The Freundlich isotherm theory says that the ratio of the amount of solute adsorbed onto a given mass of
sorbent to the concentration of the solute in the solution is not constant at different concentrations. The heat of
adsorption decreases in magnitude with increasing the extent of adsorption (Koopal et al, 1994). The linear
Freundlich isotherm is commonly expressed as follows:
logqe= log kF+ (1/n) logCe (10)
where KF and n are the Freundlich constants characteristics of the system, indicating the relative adsorption
capacity of the adsorbent related to the bonding energy and the adsorption intensity, respectively. A plot of lnqe
versus ln Ce as in(Fig.9)yielding a straight line indicates the confirmation of the Freundlich isotherm for
adsorption. The constants which are KF and 1/n can be determined from the slope and the intercept respectively
according to (Agrawal et al, 2004).
Fig. 9: Freundlich isotherm plot for the adsorption of Mn (II)
Temkin isotherm model assumes that the heat of adsorption of all the molecules in the layer decreases
linearly with the coverage of molecules due to the adsorbate–adsorbate repulsions and the adsorption of
adsorbate is uniformly distributed and that the fall in the heat of adsorption is linear rather than logarithmic. The
linearized Temkin equation is given by Eq. (11):
qe= BT ln AT+ BT ln Ce (11)
where BT = RT/bT, T is the absolute temperature in K and R is the universalgas constant (8.314 Jmol−1
K−1
).
The constant bT is related to the heat of adsorption, AT is the equilibrium binding constant (L min−1
)
corresponding to the maximum binding energy. The slope and the intercept from a plot of qe versus ln Ce as in
(Fig.10) determine the isotherm constants AT and bT.
Fig. 10: Tem kin plot for the adsorption of Co (II) at different tem peratures
296 Middle East j. Appl. Sci., 4(2): 288-299, 2014
The obtained values of applied adsorption isotherm parameters are reported in Table 2. Values
ofR2indicated that Langmuir isotherm model for the Ni(II) andCo(II) adsorption was best fitted in comparison
with Freundlichand Temkin isotherm models. The n values were found to be 11.92for the Mn(II) adsorption
onto the ResinexTM
K-8H from aqueous solution. These values are suggesting thatResinexTM
K-8H is better
adsorbent for the separation andremoval of Ni(II) and Co(II) from aqueous solution. The obtained results for the
Ni(II) and Co(II) adsorption are similar to the reported adsorbent by (Özbay, 2009, Monier et al, 2010). The
Mn(II) have opposite trend than Ni(II) and Co(II), where R2
values indicated that Freundlich isotherm model for
the Mn(II) adsorption was best fitted in comparison with Langmuir and Temkin isotherm models. The n values
were found to be 2.52 for the Mn(II) adsorption onto the ResinexTM
K-8H from aqueous solution The adsorption
capacity of adsorption and removal of Co(II), Ni(II) and Mn(II) from aqueous solution or wastewater are
tabulated in Table 2.
Table 2: Adsorption isotherm parameters of Ni(II), Co(II) and Mn(II) on ResinexTM K-8H in aqueous solution.
Langmuir parameters Freundlich parameters Temkin parameters
Qo b RL R2 n Kf R2 kT BT R2
------------------------------ ---------------------------- ----------------------------------------
Metal ions (mg/g) (L/mg) mg/g L/g J/mol
---------------------------------------------------------------------------------------------------------- Ni(II) 35.56 0.28 7.9x10-3 0.9973 11.92 54.43 0.8644 3.97x10-7 3.63 0.8731
Co(II) 43.22 5.28 4.18x10-4 0.9999 49.93 46.25 0.9202 7.1x1024 0.87 0.9194
Mn(II) 17.16 0.018 0.15 0.9965 2.00 331.00 1.0000 1.14x10-3 15.35 0.9890
Temperatures and Thermodynamics parameters of Ni(II), Co(II) and Mn(II) adsorption:
The effect of temperature on the adsorption of Ni(II), Co(II) and Mn(II)from aqueous solution onto the
ResinexTM
K-8H was performedto evaluate the influence of metal ion adsorption capacity.As it can be seen from
Fig.11, that Ni(II) and Co(II) removal tended to increase with the increase of temperatures. Enhancement of the
adsorption capacity at higher temperatures may be attributed to the enlargement of pore size and/or activation of
the adsorbent surface according to (Jhaa et al, 2008). Opposite trend was also observed for Mn(II) adsorption.
This may be due to low stability constant of Mn(II) complex with the ResinexTM
K-8H.
Fig. 11: Effect of tem perature on the adsorption uptake of a-Co (II), b-Ni (II) and c-Mn (II).
From Fig.12, thermodynamic parameters were determined for temperatures ranging from 25 to 450C using
the equilibrium constant KD (qe/Ce).
The change in free energy (∆G◦) was determined as follows (Eq. (12)):
∆G◦ = −RT ln KD (12)
where, ∆G◦ is the standard free energy (kJ/mol), R is the ideal gas constant (8.314j/mol K). The parameters
of enthalpy ∆H◦ (kJ/mol) and entropy ∆S◦ (J/mol) related to the adsorption process were calculated by equation
(13):
297 Middle East j. Appl. Sci., 4(2): 288-299, 2014
log KD = ∆S◦/R − ∆H
0/RT (13)
Fig. 12: Van’t H off plots for the adsorption uptake of Co (II), Ni (II) and Mn (II) at different tem peratures
The parameters of enthalpy (∆H◦) and entropy (∆S◦) can be calculated from the slope and the intercept of
the linear plot of logkD versus 1/T. The data obtained from the thermodynamic plots and the related parameters
are collected in Table 3. The values of ∆H◦ were positive for Ni(II) and Co(II) indicating that the adsorption
process is endothermic in nature. The positive values of ∆S◦ showed the increased randomness at the
solid/solution interface during the adsorption process. The adsorbed water molecules, which were displaced by
the adsorbate species, gained more translational energy than was lost by the adsorbate ions, thus allowing the
prevalence of the randomness in the system. The negative∆H◦ values confirmed the exothermic nature of
Mn(II)adsorption. Moreover negative ∆S◦ value showed reduction in affinityof Mn(II) onto the ResinexTM
K-
8H.In addition.Depending on types of the metal ions.The values of standard free energy change (∆G◦) were
negative under the conditions applied,the ion exchange of the metal ions was spontaneous. The values of ∆G◦
becomes more negative with the increase of temperature for Ni(II) and Co(II) indicated more efficient
adsorption at high temperature and hence its adsorption become more favorable.While for Mn(II) values of ∆G◦
becomes less negative with the increase of temperature indicated lower efficient adsorption at high temperature
and hence its adsorption become less favorable at high temperature as in(Arias and Sen, 2009, Samiey and
Toosi, 2010, Sepehra et al, 2013, Franco et al, 2013and Sharma et al, 2013). The result derived from the
references and this work indicates that the thermodynamic parameters are related to the nature of metal ions.
Table.3. Thermodynamic parameters for of Ni(II), Co(II) and Mn(II) on ResinexTM
K-8H in aqueous
solution. ∆G ∆S ∆H A Ea
(KJ/mol) (J/mol k) (KJ/mol) (kJ/mol)
----------------- ---------------- ----------------------------- Ni(II)
Temp.K
298 -0.02 183.85 56.20 3.4x10-4 6.18 308 -0.69
318 -314
Co(II) 298 -2.23 144.40 40.59 12.0x10-3 5.70
308 -10.52
318 -31.38 Mn(II)
298 1.51 -51.51 -11.49 1.15x10-5 13.54
308 1.71
318 1.97
The activation energy, Ea (kJ mol-1
) can be calculated from Fig.13 using the following equation:
logk2 = logA – Ea/RT (14)
298 Middle East j. Appl. Sci., 4(2): 288-299, 2014
The positive values of activation energy in Table 3 indicated that the minimum energy is required to
facilitate the forward (M2+
–H+) ion-exchange process and endothermic process.
Fig. 13: Arrhenius plots for the adsorption of uptake of Co(II), Ni and Mn(ii)
The order of activation energy to facilitate the ion exchange processes for thedivalent metal ions was
observed to beCo(II) >Ni(II)> Mn(II). The higher activation energy for Mn(II)–H exchange as compared to
Ni(II)–H and Co(II)–Hexchange may be considered due to higher ionic radii even though ionic mobility for the
metal ions is same(Alothman et al, 2012).
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